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RGPV CBGS 3rd Sem Electronics & Instrumentation Engineering Syllabus | EI Syllabus RGPV Credit Based Grading System B.Tech.

The Rajiv Gandhi Prodhoyogiki Vishavdhyalaya i.e RGPV now disclose the new scheme for 2nd year students who are admitted into the RGPV University as well as their affiliated institutes. The new scheme name is Credit Based Grading System (CBGS); under these scheme the university will give BTech degree to all 2nd year admitted students. It is very good news for all students and as we also known as the RGPV is one the largest government technical university of MP. More than 1 lacks candidates get Graduation as well as master degree from that university.
                   In this article we are going to share RGPV CBGS 3rd Sem EI Syllabus for 2nd year students. In the RGPV CBGS 3rd sem there are 7-8 subjects in Electronics & Instrumentation Engineering branch i.e. Energy, Environment, Ecology & Society, Electronic Devices & Circuits, Fundamentals of Measurement, Circuits analysis & synthesis, Signals and Systems, Computer Programming-I (Java), Rural Outreach (Internal Assessment), and NSS/NCC/Social Work (Internal Assessment).

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 RGPV CBGS 3rd Sem EI Syllabus

Credit Based Grading System
Electronics & Instrumentation Engineering, III-Semester
BE-3001 Mathematics-III (Syllabus for EX, EE, EI, & BM Branches)
COURSE OBJECTIVE- The objective of this course is to fulfill the needs of Engineers to understand the Applications of Fourier Series, Different Transforms, Complex Analysis & Vector Calculus in order to enable young technocrats to acquire Mathematical thinking of Formulating, Analyzing and Solving a wide range of Practical Problems Appearing in Science & EX/EE/EI/BM Engineering.

Course Contents

Fourier Series: Fourier Series for Continuous & Discontinuous Functions, Expansion of odd and even periodic functions, Half range Fourier series, Complex form of Fourier Series.
Integral Transforms:

Fourier Transform-Complex Fourier Transform, Fourier Sine and Cosine Transforms, Applications of Fourier Transform in Solving the Ordinary Differential Equation.
Laplace Transform- Introduction of Laplace Transform, Laplace Transform of elementary Functions, Properties of Laplace Transform, Change of Scale Property, First and Second Shifting Properties, Laplace Transform of Derivatives and Integrals. Inverse Laplace Transform & its Properties, Convolution theorem, Applications of Laplace Transform in solving the Ordinary Differential Equations.

Functions of Complex Variables: Analytic functions, Harmonic Conjugate, Cauchy-Riemann Equations, Line Integral, Cauchy’s Theorem, Cauchy’s Integral Formula, Singular Points, Poles & Residues, Residue Theorem , Application of Residues theorem for Evaluation of Real Integrals.

Vector Calculus: Differentiation of Vectors, Scalar and Vector Point functions, Gradient, Directional derivative, Divergence and Curl. Line Integral, Surface Integral and Volume Integral, Stoke’s Theorem and Gauss divergence theorem.

COURSE OUTCOMES- The curriculum of the Department is designed to satisfy the diverse needs of students. Coursework is designed to provide students the opportunity to learn key concepts of Fourier Series, Different Transforms, Complex Analysis & Vector Calculus.

EVALUATION- Evaluation will be continuous, an integral part of the class as well as through external assessment.
1.         Erwin Kreyszig: Advanced Engineering Mathematics, Wiley India.
2.         H C Taneja: Advanced Engineering Mathematics, I.K. International Publishing House Pvt. Ltd.
3.         C B Gupta & S R Singh : Engineering Mathematics , Mc Graw Hill Education.
4.         S S Sastri: Engineering Mathematics, PHI
5.         Ramana: Advance Engg. Mathematics,  TMH New Delhi
6.         Engineering Mathematics By Samnta Pal and Bhutia, Oxford Publication

Credit Based Grading System
Electronics & Instrumentation Engineering, III-Semester
EI-3002 Electronic Devices and Circuits

Basics of semiconductor devices

Intrinsic & Extrinsic semiconductors, Mobility and Conductivity, Hall effect, E-K diagram, Current Densities, Diffusion, Generation & Recombination of electron-hole pair, Continuity equation, Conductivity Modulation, Mass-action Law, Injected Minority Carrier Charge, p-n junction diode, V-I characteristics & their temperature dependence, Diode resistances, and capacitance, Breakdown diodes, Photodiodes, LEDs, Varacter Diode, Schottky Diode, Tunnel Diode,
Diode and Transistor circuits

Clippers, Clampers, Clamping theorem, Rectifiers & filters, Model of diode, Bipolar junction transistor (BJT), Potential profile in PNP & NPN structures, Current components, Configurations, Early Effect, Eber’s Moll Model, Transistor as an amplifier, Biasing & Thermal Stabilization, The Q point stability, Stabilization against variation of ICO, VBE & β, Bias compensation, Millers theorem and its dual, Thermal runway, Schottky and Photo-transistors.

BJT Modelling and Introduction to FET

Hybrid model, Simplified model, Common emitter with emitter resistor, high i/p impedance circuits, Emitter follower, comparison of CB, CE, CC configuration, Darlington pair, Bootstrapping, Cascode Amplifier, Field effect transistors(FET), JFET, pinch off, V-I Characteristics, Small signal model, MOSFET, Derivation for drain current ID for E-MOSFET, Threshold voltage and body effect, CS & CD amplifiers, Biasing techniques, FET as VDR,

MOS Structure and Short channel effect theory

Band diagram for a MOS junction under accumulation, Depletion & inversion, MOS capacitor, C-V of an ideal & non- ideal capacitors, Characterization of MOS capacitors, MOS field effect transistor (MOSFET) V-I characteristics in three regions of operation & equivalent circuit. Short channel MOSFET: Effect of scaling of MOSFET, Short & narrow channel effects on V-I characteristics, Hot electron effect in MOSFET.

Silicon Processing and Introduction to Power electronic devices

Silicon Planar technology, Oxidation, Diffusion, Metallization, Ion-Implantation & chemical vapor deposition, Lithographic process, Typical Bipolar & MOS IC process sequence, Silicon controlled Rectifier, Holding and Latching current, di/dt triggering and other triggering methods & Unijunction Transistor (UJT) and UJT relaxation oscillator.

Text Books Recommended:
1.         Jacob Millman & Christos C. Halkias Electronic Devices & Circuits McGraw-Hill 1967.
2.         Robert L. Boylestad, Electronic devices and Circuits, PHI.
3.         Ben G. Streetman, Solid State Electronics Devices, Prentice Hall of India, 5th edition.
4.         Tyagi M. S., Semiconductor Materials and Devices, John Wiley, 4th edition.

Reference Books:
1.         S. M. Sze, Physics of Semiconductor Devices, Wiley-Interscience, 1969.
2.         Sedra & Smith L, Electronic circuits, McGraw Hill.
3.         John D. Ryder, Electronics fundamentals & Applications, PHI.
4.         Milliman and Grabel, Microelectronics, TMH.

Credit Based Grading System
Electronics & Instrumentation Engineering, III-Semester
EI-3003 Fundamentals of Measurement

Fundamentals of measuring instruments: Fundamental methods of measurement, Classification of measuring instruments, Static and Dynamic characteristics, Error Classification and analysis, Standards for displacement, force, time, frequency, temperature and electrical standards. IEEE standards.

Cathode Ray Oscilloscope: construction and operation, measurement of amplitude, phase and frequency with cro, lissajous patterns. Fundamentals of EMI, RF measurements techniques, Network analyzers, Noise reduction techniques, compatibility of measuring instruments.

Analog Instruments: Analog indicating type instruments based on various operating principles, ammeters, voltmeters, ohmmeters. Extension of instrument range, instrument transformers.

Measurement of low resistances, voltage, current, phase, frequency, power and energy, Q factor, resistance, noise etc; compensation, calibration and testing of measuring instruments.

A.C. Bridges: A.C bridges for measurement of inductance, capacitance, Q factor and loss angle, universal impedance bridge. Design aspects. Design aspects of digital Multimeter and panel meters, Distortion and spectrum analysis.

1.         A.K. Sawhney, Electrical & Electronic Measurement & Instrumentation.
2.         D.S Kumar, “Measurement Systems: Applications & design”
3.         B.C.Nakra & K.K.Choudhary, “Instrumentation measurement & analysis”
1.         W.D. Cooper, Electronic Measurement, Pearson Education
2.         Terman & Petit, Electronic Measurement.
3.         Carr, Instrumentation, Pearson Education

Credit Based Grading System
Electronics & Instrumentation Engineering, III-Semester
EI-3004 Circuits Analysis and Synthesis

Basics of electrical Networks

Network elements: E.M.F., Potential and Potential difference, Current and Current density, Ideal and practical Voltage and Current Source and their characteristics, source transformations, Various network elements and their behavior, Power and energy relations, Kirchhoff’s laws, Current and voltage division, Nodal and Mesh analysis, Graph theory, Incidence and Reduced incidence matrix, isomorphic graph, Tie-set and Cut-set matrix.

Network Theorems & Filter circuits

Superposition, Reciprocity, Thévenin’s, Norton’s and Maximum power transfer, Compensation, Tellenge’s. ∆-Y transformation, Polyphase analysis, Power relation in AC Circuits, Power factor, Apparent and reactive power, Power triangle, Sinusoidal steady state analysis of RLC circuits, Passive filters, High pass and Low pass, Band pass & Band stop filter, Prototype & m-derived filters, Fundaments of active filters.

Analysis of Coupled Circuits & Resonance

Magnetic coupling, Study of ideal transformer, Time domain, natural response and forced response, Dot convention, electrical equivalent of magnetically coupled circuits, single and double tuned coupled circuits, Resonance: Series and parallel resonance, bandwidth &selectivity, Q-factor, Effect of resistance on frequency response curve, Parallel resonance of RLC circuit.

Two port network analysis & Network Functions

Various network parameters: Z, Y, Hybrid, ABCD & their relationships condition of reciprocity and symmetry, Input and output impedances, Equivalent Т and П sections representation in parameter form, Ladder network, Network Function, Driving point and transfer impedances, Interpretation of poles and zeros, effect of their location in complex plane. Routh-Hurwitz Criterion of stability.

Time Domain Analysis of Circuits and Concept of Network Synthesis

Transient and steady state response of electrical circuits, Initial conditions & final condition, step and impulse response, Network Synthesis: Hurwitz polynomial, Positive Real (PR) function, Properties of LC, RC, RL immittances, Foster realization of LC circuits, Ladder development and Cauer forms, Significance of elements in Foster & Cauer forms, Determination of end elements, Applicability of Foster and Cauer forms.

1.         John D. Ryder & Charles M. Thomson Electronic Circuits & Systems Prentice-Hall Inc. 1976
2.         Van Valkenburg M.E., Network Analysis, Third Edition, Pearson Education.
3.         D. Roy Choudhury, Networks and Systems, New Age International, 1988
4.         William H. Hayt & Jack E. Kemmerly Engineering Circuit Analysis McGraw-Hill Book Company Inc. 1971

1.         Desoer and Kuh, Basic Circuit Theory, McGraw Hill.
2.         Franklin F. Kuo Network Analysis & Synthesis Wiley Toppan 2nd.ed. 1966
3.         Van Valkenburg M.E., Introduction to Modern Network Synthesis, PHI.

Credit Based Grading System
Electronics & Instrumentation Engineering, III-Semester
EI-3005 Signals and Systems


Continuous-Time and Discrete-Time Signals- Unit Impulse, Unit Step, Ramp, Exponential & Sinusoidal Signals. Periodic & aperiodic signals, Deterministic and random signals, Energy and Power signals. Continuous-Time and Discrete-Time Systems. Classification, Static & dynamic, Linear and non-linear, Causal and non-causal, Time variant and invariant, Continuous-Time LTI Systems: The Convolution Integral. Discrete-Time LTI Systems: The Convolution Sum.


Fourier series Representation of Continuous-Time Periodic Signals, Properties, Continuous-Time Fourier Transform (CTFT), The Fourier Transform for Periodic Signals, Properties of the CTFT, Duality, Sinc and signum function, Sampling Theorem, Aliasing, Discrete Time Fourier series Properties, Discrete-Time Fourier Transform (DTFT). Properties of the DTFT. Parseval's Theorem, Central ordinate theorem.


Definition, Region of Convergence, Inverse Laplace Transform, Properties, Analysis and Characterization of LTI Systems Using the Laplace Transform, The Unilateral Laplace Transform, Casualty and stability in continuous time LTI system, System realization through Block-diagram representation and system interconnection, State variable analysis, State space Models, Solution of State equation, The state-transition matrix, Concept of Controllability and Observability.


Definition, Region of Convergence. Inverse z-Transform. Properties, Some Common z-Transform Pairs. Analysis and Characterization of LTI Systems Using z-Transforms. System Function Algebra and Block Diagram Representations. The Unilateral z-Transforms. Casualty and stability in continuous time LTI system, Group delay, Phase delay.


Sets and Sample Spaces Random Variables Continuous and Discrete, Cumulative distribution Function (CDF), Probability Density Function (PDF), Expectation and Moments, Types of Random Processes, Ergodicity, Auto-correlation Function (ACF) & Cross correlation Function (CCF), Power Spectral Density, Wiener– Khinchin–Einstein theorem, Central limit theorem, Transmission of a random process through a Linear Filter. Central Limit Theorem, Mixing of a Random process with sinusoidal process.

1.         Allen. V. Oppenheim, A.S. Willsky and I.T. Young, "Signals and Systems", Prentice Hall, 1983.
2.         B.P. Lathi, "Signal Processing and Linear Systems", Oxford University Press, c1998.
3.         Venkatarama Krishnan, "Probability and Random Processes", ohn Wiley & Sons, 2006
1.         Simon Haykin, Barry van Veen, "Signals and Systems", John Wiley and Sons (Asia) Private Limited, c1998.
2.         S. Palaniammal, "Probability and Random Processes", PHI Learning, 2012

Credit Based Grading System
Electronics & Instrumentation Engineering, III-Semester
EI-3006 Computer Programming-I (JAVA)

Basic Java Features - C++ Vs JAVA, JAVA virtual machine, Constant & Variables, Data Types, Class, Methods, Objects, Strings and Arrays, Type Casting, Operators, Precedence relations, Control Statements, Exception Handling, File and Streams, Visibility, Constructors, Operator and Methods Overloading, Static Members, Inheritance: Polymorphism, Abstract methods and Classes

Java Collective Frame Work - Data Structures: Introduction, Type-Wrapper Classes for Primitive Types, Dynamic Memory Allocation, Linked List, Stack, Queues, Trees,
Generics: Introduction, Overloading Generic Methods, Generic Classes, Collections: Interface Collection and Class Collections, Lists, Array List and Iterator, Linked List, Vector.

Collections Algorithms: Algorithm sorts, Algorithm shuffle, Algorithms reverse, fill, copy, max and min Algorithm binary Search, Algorithms add All, Stack Class of Package java. Util, Class
Priority Queue and Interface Queue, Maps, Properties Class, Un-modifiable Collections.

Advance Java Features - Multithreading: Thread States, Priorities and Thread

Scheduling, Life Cycle of a Thread, Thread Synchronization, Creating and Executing Threads, Multithreading with GUI, Monitors and Monitor Locks. Networking: Manipulating URLs, Reading a file on a Web Server, Socket programming, Security and the Network, RMI, Networking, Accessing Databases with JDBC: Relational Database, SQL, MySQL, Oracle

Advance Java Technologies - Servlets: Overview and Architecture, Setting Up the

Apache Tomcat Server, Handling HTTP get Requests, Deploying a web Application, Multitier Applications, Using JDBC from a Servlet, Java Server Pages (JSP): Overview, First JSP Example, Implicit Objects, Scripting, Standard Actions, Directives, Multimedia: Applets and Application: Loading, Displaying and Scaling Images, Animating a Series of Images, Loading and playing Audio clips

Advance Web/Internet Programming (Overview): J2ME, J2EE, EJB, XML.

1.         Deitel & Deitel, ”JAVA, How to Program”; PHI, Pearson.
2.         E. Balaguruswamy, “Programming In Java”; TMH Publications
3.         The Complete Reference: Herbert Schildt, TMH
4.         Peter Norton, “Peter Norton Guide To Java Programming”, Techmedia.
5.         Merlin Hughes, et al; Java Network Programming , Manning Publications/Prentice Hall
List of Program to be perform (Expandable)

1.         Installation of J2SDK

2.         Write a program to show Concept of CLASS in JAVA
3.         Write a program to show Type Casting in JAVA
4.         Write a program to show How Exception Handling is in JAVA
5.         Write a Program to show Inheritance and Polymorphism
6.         Write a program to show Interfacing between two classes
7.         Write a program to Add a Class to a Package
8.         Write a program to demonstrate AWT.
9.         Write a program to Hide a Class
10.       Write a Program to show Data Base Connectivity Using JAVA
11.       Write a Program to show “HELLO JAVA ” in Explorer using Applet
12.       Write a Program to show Connectivity using JDBC
13.       Write a program to demonstrate multithreading using Java.
14.       Write a program to demonstrate applet life cycle.

RGPV CBGS 3rd Sem EI Subject list

RGPV CBGS 3rd Sem Subjects EI | Bachelor of Technology B.Tech. (Electronics & Instrumentation Engineering)

S. NO.
Subject Code
 Subject Name
Energy, Environment, Ecology & Society
Electronic Devices & Circuits
Fundamentals of Measurement
Circuits analysis & synthesis
Signals and Systems
Computer Programming-I (Java)
Rural Outreach (Internal Assessment)
NSS/NCC/Social Work (Internal Assessment)

Download RGPV CBGS 3rd Sem Electronics & Instrumentation Engineering Syllabus

source: www.rgpv.ac.in


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